Light does not have mass, light is an electromagnetic wave.Light does have momentum, which is what might be getting you here.

E=mc^2P=mv, where v=c, P=mcm=E/(c^2)sub m into P=mcP=E*c/(c^2)=E/c

Momentum of a quanta of light is equal to the energy of the photon divided by its velocity.

However, light still does not have mass, I used the equivalency principle that mass and energy are interchangeable, and light is energy.Hence, as an energy, can be entered into the momentum equation.

Light can be bent by very large gravitational forces, hence gravitational lensing. But when I say very large, I'm talking stellar-mass-sized. Not Earth-sized (which is pathetically small).

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Why light produces waves, because it weighs. Let us remember that the waves produces a touch.

You are confusing matter waves and energy waves. Pick up a physics text book and actually read it. Seriously.

Light form some sources does not appear to reach the clouds because the light emmitted from the sources spreads out over the distance.The intensity of light form a source decreases over distance by the inverse square law.

Do you actually read what anyone says?

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Buy a physics textbook

Do it. Do it now.

_________________"Don't tell me that man doesn't belong out there. Man belongs wherever he wants to go--and he'll do plenty well when he gets there."Wernher von Braun, Time magazine, 1958

My advice is abandon whatever you currently think you know and start from scratch. Sounds hard, but you've clearly messed up something fundamental when you were attempting to learn, and now you can't grasp this physics.

_________________"Don't tell me that man doesn't belong out there. Man belongs wherever he wants to go--and he'll do plenty well when he gets there."Wernher von Braun, Time magazine, 1958

If "It is an electromagnetic wave composed of fluctuating electric fields orthogonal to fluctuating magnetic fields that perpetuate between Yes.", then it has weight. Let us remember that the waves are produced by a touch.

There is no logical way that you can get from what I said to your conclusion.Electromagnetic waves have no mass, they have no weight.They are energy, not mass.

_________________"Don't tell me that man doesn't belong out there. Man belongs wherever he wants to go--and he'll do plenty well when he gets there."Wernher von Braun, Time magazine, 1958

Maybe you should start discussing your ideas with people that speak your language first. Even if we disregard most of the logical problems, some of your statements still do not make any sense whatsoever...

Are therw conditions where energy can be made into sub atomic particles?

Yes that is what a lot of those experiments at CERN are all about creating and studying subatomic particles created from the energy given off by collisions of bits of matter and antimatter accelerated to near light speed.

_________________Someone has to tilt at windmills.So that we know what to do when the real giants come!!!!

You don't need mass to propel something, you need momentum (mass times velocity). The law of momentum conservation says that if matter is thrown out the back of a rocket with some momentum, the rocket gains an equal amount of momentum in the opposite direction.

Light does have momentum,* so all you need to do is shine a laser beam in one direction, and you'll accelerate in the other direction.

Of course, this doesn't work so well in practice. This is because you need a lot of energy to produce enough light to propel anything. The equation that relates energy and momentum for light is:

E=pc

where p is momentum and c is the speed of light. If you plug in numbers, you'll find that you need a lot of energy to produce a beam of light with any useful amount of momentum. That's why you don't fall over when you fire up your laser pointer.

I'm certain that people have thought of doing propulsion using high intensity lasers, but I would suspect that it would be highly impractical with today's technology.

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*You might ask how light can have momentum, given that momentum is defined as mass times velocity. In the case of massless matter like light, we make an exception and define momentum (for a photon) as p=h/l, where h is Planck's constant, and l is the length (if you're skeptical, check the units).